An Investigation into the Mechanisms of DNA Strand Breakage by

Dec 7, 2006 - DNA Damage by the Direct Effect of Ionizing Radiation: Products Produced by Two Sequential One-Electron Oxidations. David M. Close , Wil...
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J. Phys. Chem. B 2006, 110, 26286-26291

An Investigation into the Mechanisms of DNA Strand Breakage by Direct Ionization of Variably Hydrated Plasmid DNA Shubhadeep Purkayastha,† Jamie R. Milligan,‡ and William A. Bernhard*,† Department of Biochemistry and Biophysics, UniVersity of Rochester, Rochester, New York 14642, and Department of Radiology, UniVersity of California at San Diego, La Jolla, California 92093-0610 ReceiVed: August 24, 2006; In Final Form: October 25, 2006

The mechanisms by which ionizing radiation directly causes strand breaks in DNA were investigated by comparing the chemical yield of DNA-trapped free radicals to the chemical yield of DNA single strand break (ssb) and double strand break (dsb), as a function of hydration (Γ). Solid-state films of plasmid pUC18, hydrated to 2.5 < Γ< 22.5 mol, were X-irradiated at 4 K, warmed to room temperature, and dissolved in water. Free radical yields were determined by EPR at 4 K. With use of the same samples, Gel electrophoresis was used to measure the chemical yield of total strand breaks, which includes prompt plus heat labile ssb; G′total(ssb) decreased from 0.092 ( 0.016 µmol/J at Γ) 2.5 to 0.066 ( 0.008 µmol/J at Γ) 22.5. Most provocative is that at Γ) 2.5 the yield of total ssb exceeds the yield of trapped deoxyribose radicals: G′total(ssb) - G′sugar(fr) ) 0.06 ( 0.02 µmol/J. Nearly 2/3 of the strand breaks are derived from precursors other than radicals trapped on the deoxyribose moiety. To account for these nonradical precursors, we hypothesize that strand breaks are produced by two one-electron oxidations at a single deoxyribose residue within an ionization cluster.

Introduction Direct-type effects, that is damage caused by direct ionization of DNA or by transfer of electrons or holes from the hydration shell to the DNA, contribute between 40% and 50% of the damage that causes cell death.1-5 The remainder is due to indirect effects, which are mediated by water radicals. The latter is more easily studied and, therefore, is better characterized, both quantitatively and mechanistically.3,6,7 Here we focus on strand break (sb) formation by direct-type effects, using variable levels of hydration to gain insight into the mechanisms responsible for sb produced by direct-type effects. As the hydration level decreases, the contribution of the direct effect increases. The level of DNA hydration, Γ (mol water/mol nucleotide), has been shown to influence the yields of direct-type damage in DNA exposed to ionizing radiation.8-17 For water radical cations (holes) formed in the tightly bound solvation shell (Γ < 9-10) of DNA, hole transfer to the deoxyribose backbone and bases occurs rapidly; for the outer lying waters (9-10 < Γ < 23), the rate at which the water radical cation (H2O•+) deprotonates (to HO•) is faster than the transfer rate, with the result that HO• formation dominates.12,13,16 Thus, the effective target mass per nucleotide, with respect to hole trapping in DNA as detected by EPR, consists of the nucleotide residue itself, one counterion, and 9 to10 waters per nucleotide. The role of these tightly bound waters is likely to be significant given the high concentration of DNA in vivo.18 In nucleosomes, it has been estimated at 0.17 g/mL,19 which corresponds to a Γ of ca. 100 mol water/mol nucleotide. * To whom correspondence should be addressed. E-mail: [email protected]. Fax: (585) 275-6007. Phone: (585) 275-3730. † University of Rochester. ‡ University of California at San Diego.

Via the direct effect, radiation forms radical cations on the deoxyribose-phosphate backbone of DNA. If the backbone radical cation deprotonates, the hole (any site that has lost one electron) is irreversibly trapped as a neutral carbon-centered radical, a known precursor to strand breaks.3 The fact that such deoxyribose damage releases an unaltered free base20 was used by Swarts et al. to measure the chemical yield of free base release as a proxy for the yield of sb formation in lyophilized salmon sperm DNA γ-irradiated at room temperature.9 In a more recent work, Yokoya et al. measured total single strand breaks (ssb) for solid-state pUC18 γ-irradiated at 5.6 °C.21 Recently we reported that in X-irradiated plasmid DNA hydrated to Γ ) 22.5 mol water/mol nucleotide, the yield of total ssb significantly exceeds the yield of trapped deoxyribose radicals.22 In plasmid pUC18 X-irradiated at 4 K, the yield of radicals trapped on the deoxyribose moiety, Gsugar(fr), and the total yield of single strand breaks, G′total(ssb), were found to be 0.06 and 0.14 µmol/J, respectively. We termed the difference between G′total(ssb) and Gsugar(fr), 0.14 µmol/J - 0.06 µmol/J ) 0.08 µmol/J, the shortfall because this is the fraction of ssb that cannot be accounted for by EPR detected radicals trapped on deoxyribose. One mechanism that could explain the shortfall is hydrogen abstraction by hydroxyl radicals formed in the outer solvation shell (Γ > 9-10). A way to test for the possibility of hydroxyl radical attack, which is an indirect effect, is to vary the level of DNA hydration. In the present study, the level of hydration was varied from Γ of 2.5 to 22.5 mol water/mol nucleotide. In the course of doing so, we became aware of an error in our earlier work22 related to the choice of target mass used in comparing free radical yields with strand break yields. For radical yields, we employed a target mass consisting of the entire sample (DNA + solvation shell + a small excess of salt) and for sb yields we employed only DNA in the target mass. It is important, however, to utilize the same target mass for both types of yield calculation.

10.1021/jp065489i CCC: $33.50 © 2006 American Chemical Society Published on Web 12/07/2006

DNA Strand Breakage

J. Phys. Chem. B, Vol. 110, No. 51, 2006 26287

In this work, that error is corrected by employing DNA plus its solvation shell as the target mass for all of the yield calculations. This correction has a large impact at Γ ) 22.5, where evidence of a shortfall is no longer readily apparent. However, at low levels of hydration, Γ < 10, it is demonstrated that the shortfall is of significant magnitude. The dependency of the shortfall on the degree of hydration argues persuasively against a hydroxyl radical attack mechanism and supports instead a mechanism entailing two one-electron oxidation events at a single deoxyribose. Materials and Methods The purification of plasmid pUC18(2686 bp), sample preparation,22,23 and procedures for sample irradiation17 have all been described previously. In brief, solid-state film samples of pUC18 plasmid were equilibrated to various levels of hydration (Γ in mol water/mol nucleotide). The films consist of between (92 ( 3)% and (87 ( 4)% DNA, decreasing slightly as Γ increases. The remaining mass is excess salt coming from the 5 mM phosphate buffer employed in the starting solution. Samples were irradiated at 4 K in a Janis Dewar setup24 with X-rays generated by a Varian/Eimac OEG-76H tungsten-target tube operated at 70 kV and 20 mA and filtered by a 25 µm aluminum foil. The dose rate was 24 kGy/h. Procedures for agarose gel electrophoresis and strand break assay have been described previously.22 Following EPR spectroscopy the films were warmed to room temperature and dissolved in 1X TE buffer (10-2 mol dm-3 Tris, 10-3 mol dm-3 EDTA, pH 8.0) to 10-fold their weight in volume. Aliquots, added to a loading buffer containing 0.1% bromphenol blue, were assayed by agarose gel electrophoresis at 4 °C in TBE (89 mmol dm-3 boric acid, 89 mmol dm-3 Tris, 1 mmol dm-3 EDTA). The gels were stained with SYBR Green I dye (Molecular Probes, Eugene, OR). The incremental increase in sb yield obtained by post-irradiation heat treatment at 75 °C for 30 min is considered to be the yield of heat labile sites. It is important to note that sb yields are calculated differently than in our previous work. Previously we based the yields of strand breaks on energy absorbed by a target mass consisting of only the mass of DNA. In the current work, the target mass consists of DNA plus the solvent shell. The concentration of trapped free radicals in plasmids was determined by EPR at 4 K after X-irradiation at 4 K. The EPR spectra show no radicals assignable to excess salt, only DNA trapped radicals. Following EPR, these same samples were used for strand break measurements as described above. The yield of radicals trapped by DNA at 4 K was calculated differently than in our previous work. In past work,16,17,22,25-27 the target mass was based on sample mass, consisting of DNA plus solvation shell plus, in the case of films, a small (usually 9-10), and (4) two one-electron oxidations at a single deoxyribose. We argue below that the effect of hydration on the shortfall excludes (3), but while it is inconsistent with (1) it is consistent with (4). Dissociative Electron Attachment (DEA). Sanche and collaborators have shown that low-energy electrons (LEE),